Food, water, and fault lines: Remote sensing opportunities for earthquake-response management of agricultural water

Rodriguez, Jenna; Ustin, Susan L.; Sandoval-Solís, Samuel; O’Geen, A. T.

doi:10.1016/j.scitotenv.2016.05.146

Cited by 15 publications

(7 citation statements)

References 59 publications

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“…The geophysical ERT results underscore the importance of improving our understanding of hydrogeological and agricultural systems by installing a network of groundwater monitoring sites and conducting specifically designed agro-geophysical experiments in seismically active areas. Agricultural food production and its vulnerability to seismic events are directly related to food security and economic condition of a region (Rodriguez et al, 2016), particu-larly in developing countries like Pakistan, where agriculture plays a vital role in the economy as well as a major source of food for its large population. Hence, the changing patterns of soil moisture content within rooting depth, presence of sand blows, severe damages to bridges and extensive lateral spreading observed on both banks of the UJC in the immediate vicinity of reservoir area highlight the importance of the presented work for agricultural disaster management in the study area and other similar seismically active zones in the world.…”

Section: Implications Of Liquefaction-induced Deformation For Coseismmentioning

confidence: 99%

Investigation of coseismic liquefaction‐induced ground deformation associated with the 2019 M_w 5.8 Mirpur, Pakistan, earthquake using near‐surface electrical resistivity tomography and geological data

Khan

Turab

Riaz

et al. 2021

Near Surface Geophysics

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An electrical resistivity tomography survey was conducted to assess the subsurface conditions associated with the coseismic liquefaction phenomenon in the epicentral region following the M w 5.8 Mirpur earthquake (Pakistan) on 24 September 2019. The Mirpur earthquake produced extensive coseismic liquefaction-induced surface deformations, including: sand blows, ground failure and lateral spreading along the Upper Jhelum Canal and in the nearby villages. Electrical resistivity data were acquired along three profiles and calibrated with available borehole data. The inverted electrical resistivity tomography profiles reveal three regional geoelectric layers, which consist of an upper 2--5-m-thick discontinuous zones of medium resistivity values ranging from 25 m to 60 m, underlain by a 7-8-m-thick zone of low resistivity (<10 m) and a basal layer of high resistivity (> 100 m). Based on geological and geophysical data, we infer that. (1) disrupted geoelectric layers in the shallow subsurface and spatially extended low electrical resistivity (<8 m) layers document the elevated groundwater table due to sudden increase in pore-water pressure triggered by the Mirpur earthquake. These lenses of high conductivity may represent potential hazards in the case of future earthquakes in the study area. (2) Fracture azimuths vary between 120°± 15°and 335°-45°(subparallel and orthogonal to the strike of the Himalayan Frontal Thrust. (3) Common coseismic deformational features (e.g., sand blow and ground fracture) are located within the zone of maximum-recorded ground shaking (intensity of VI) and underlain by Quaternary alluvial sediments. (4) Mega fractures (1.60 m wide and up to 187 m long) oriented parallel to the canal resulted from lateral spreading. We conclude that high resistivity structures extending from depth to the shallow subsurface resulted from either intrusion of air or eruption of sands from layer three. We suggest that high-resolution geoelectrical imaging

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Section: Implications Of Liquefaction-induced Deformation For Coseismmentioning

confidence: 99%

Investigation of coseismic liquefaction‐induced ground deformation associated with the 2019 M_w 5.8 Mirpur, Pakistan, earthquake using near‐surface electrical resistivity tomography and geological data

Khan

Turab

Riaz

et al. 2021

Near Surface Geophysics

View full text Add to dashboard Cite

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“…They also encompass data across various time intervals, from hourly to daily, monthly, and yearly. Moreover, they make it feasible to examine changes and monitor terrestrial events using these data (Ge et al, 2019), including agricultural and natural resources management (Rodriguez et al, 2015), groundwater (Ollivier et al, 2021), water quality (Li et al, 2021), salinity management (Apan et al, 2004), and crop water requirement (Salehnia et al, 2018;Olivera Rodriguez et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Evaluation of CRU TS, GPCC, AgMERRA, and AgCFSR meteorological datasets for estimating climate and crop variables: A case study of maize in Qazvin Province, Iran

2022

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In the past few decades, meteorological datasets from remote sensing techniques in agricultural and water resources management have been used by various researchers and managers. Based on the literature, meteorological datasets are not more accurate than synoptic stations, but their various advantages, such as spatial coverage, time coverage, accessibility, and free use, have made these techniques superior, and sometimes we can use them instead of synoptic stations. In this study, we used four meteorological datasets, including Climatic Research Unit gridded Time Series (CRU TS), Global Precipitation Climatology Centre (GPCC), Agricultural National Aeronautics and Space Administration Modern-Era Retrospective Analysis for Research and Applications (AgMERRA), Agricultural Climate Forecast System Reanalysis (AgCFSR), to estimate climate variables, i.e., precipitation, maximum temperature, and minimum temperature, and crop variables, i.e., reference evapotranspiration, irrigation requirement, biomass, and yield of maize, in Qazvin Province of Iran during 1980-2009. At first, data were gathered from the four meteorological datasets and synoptic station in this province, and climate variables were calculated. Then, after using the AquaCrop model to calculate the crop variables, we compared the results of the synoptic station and meteorological datasets. All the four meteorological datasets showed strong performance for estimating climate variables. AgMERRA and AgCFSR had more accurate estimations for precipitation and maximum temperature. However, their normalized root mean square error was inferior to CRU for minimum temperature. Furthermore, they were all very efficient for estimating the biomass and yield of maize in this province. For reference evapotranspiration and irrigation requirement CRU TS and GPCC were the most efficient rather than AgMERRA and AgCFSR. But for the estimation of biomass and yield, all the four meteorological datasets were reliable. To sum up, GPCC and AgCFSR were the two best datasets in this study. This study suggests the use of meteorological datasets in water resource management and agricultural management to monitor past changes and estimate recent trends.

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“…Increased availability of high-resolution satellite images is driving the rapid expansion in remote sensing applications, including commercial, industrial, governmental, and research domains [1][2][3][4][5][6][7][8][9][10]. High-resolution satellite images are also commonly used in urban remote sensing applications, such as change detection, urban sprawl, land use/land cover mapping, environmental studies, and transportation [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

Orthorectification of WorldView‐3 Satellite Image Using Airborne Laser Scanning Data

et al. 2021

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Satellite images have been widely used to produce land use and land cover maps and to generate other thematic layers through image processing. However, images acquired by sensors onboard various satellite platforms are affected by a systematic sensor and platform-induced geometry errors, which introduce terrain distortions, especially when the sensor does not point directly at the nadir location of the sensor. To this extent, an automated processing chain of WorldView-3 image orthorectification is presented using rational polynomial coefficient (RPC) model and laser scanning data. The research is aimed at analyzing the effects of varying resolution of the digital surface model (DSM) derived from high-resolution laser scanning data, with a novel orthorectification model. The proposed method is validated on actual data in an urban environment with complex structures. This research suggests that a DSM of 0.31 m spatial resolution is optimum to achieve practical results (root-mean-square error = 0.69 m ) and decreasing the spatial resolution to 20 m leads to poor results (root-mean-square error = 7.17 ). Moreover, orthorectifying WorldView-3 images with freely available digital elevation models from Shuttle Radar Topography Mission (SRTM) (30 m) can result in an RMSE of 7.94 m without correcting the distortions in the building. This research can improve the understanding of appropriate image processing and improve the classification for feature extraction in urban areas.

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Food, water, and fault lines: Remote sensing opportunities for earthquake-response management of agricultural water

Cited by 15 publications

References 59 publications

Investigation of coseismic liquefaction‐induced ground deformation associated with the 2019 M_w 5.8 Mirpur, Pakistan, earthquake using near‐surface electrical resistivity tomography and geological data

Investigation of coseismic liquefaction‐induced ground deformation associated with the 2019 M_w 5.8 Mirpur, Pakistan, earthquake using near‐surface electrical resistivity tomography and geological data

Evaluation of CRU TS, GPCC, AgMERRA, and AgCFSR meteorological datasets for estimating climate and crop variables: A case study of maize in Qazvin Province, Iran

Orthorectification of WorldView‐3 Satellite Image Using Airborne Laser Scanning Data

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Food, water, and fault lines: Remote sensing opportunities for earthquake-response management of agricultural water

Cited by 15 publications

References 59 publications

Investigation of coseismic liquefaction‐induced ground deformation associated with the 2019 Mw 5.8 Mirpur, Pakistan, earthquake using near‐surface electrical resistivity tomography and geological data

Investigation of coseismic liquefaction‐induced ground deformation associated with the 2019 Mw 5.8 Mirpur, Pakistan, earthquake using near‐surface electrical resistivity tomography and geological data

Evaluation of CRU TS, GPCC, AgMERRA, and AgCFSR meteorological datasets for estimating climate and crop variables: A case study of maize in Qazvin Province, Iran

Orthorectification of WorldView‐3 Satellite Image Using Airborne Laser Scanning Data

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Product

Resources

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Investigation of coseismic liquefaction‐induced ground deformation associated with the 2019 M_w 5.8 Mirpur, Pakistan, earthquake using near‐surface electrical resistivity tomography and geological data

Investigation of coseismic liquefaction‐induced ground deformation associated with the 2019 M_w 5.8 Mirpur, Pakistan, earthquake using near‐surface electrical resistivity tomography and geological data